# Active and Nonlinear Models for Cochlear Mechanics

> **NIH NIH R01** · UNIVERSITY OF MICHIGAN AT ANN ARBOR · 2020 · $303,934

## Abstract

PROJECT SUMMARY:
Fluid flow stimulates the hair bundles (HB) of the inner hair cells (IHC) of the cochlea opening the mechano-
electric transducer (MET) channels of the IHCs. The resulting current depolarizes the cell body inducing
neurotransmitter release and, ultimately, auditory nerve stimulation. The active machinery of the cochlea, driven
by motility of outer hair cells (OHC), both tunes the microfluidic excitation of the IHC HBs and provides for
nonlinear compression. However, the relative influence of OHC somatic and HB motility on this final fluidic
forcing in the cochlea has yet to be conclusively determined. Further, the manner in which the IHC HBs are
physically excited, whether by the influence of shear motion of the fluid or by a pressure difference induced
pulsatile flow has yet to be determined. The specific aims of this grant are to develop mathematical models of
these phenomenon and rigorously test these hypotheses via comparison to existing experiments and work with
our collaborators to devise feasible new experiments to test our predictions. In addition to predicting the
response of the cochlea, we emphasize the importance of determine the noise present in the system when no
stimulus is present; a computation that sets the lowest sound that can be sensed (as the signal must exceed
the noise) – another test of the models.
The overarching goal of this research is to develop a complete fluid-mechanical-electrical model that describes
the response of the cochlea to both external acoustic and internal electrical stimulation. If successful, this
model will enhance our understanding of failure mechanisms in the cochlea, answering important questions as
to the morphological elements of the cochlea that fail and why. Such understanding will improve noninvasive
diagnosis of hearing as abnormalities in the response can be linked to specific pathologies. Further, as our
model can predict the interaction of electrical and acoustic amplification. Finally, having an understanding of
how the cochlea process sound over the entire spectrum will help us to understand how important classes of
signals are processed in the cochlea (such as speech and music) and such understanding can lead to better
speech processing algorithms or cochlear implant electrical stimulation approaches.

## Key facts

- **NIH application ID:** 9879734
- **Project number:** 5R01DC004084-18
- **Recipient organization:** UNIVERSITY OF MICHIGAN AT ANN ARBOR
- **Principal Investigator:** Karl Grosh
- **Activity code:** R01 (R01, R21, SBIR, etc.)
- **Funding institute:** NIH
- **Fiscal year:** 2020
- **Award amount:** $303,934
- **Award type:** 5
- **Project period:** 1999-05-01 → 2023-02-28

## Primary source

NIH RePORTER: https://reporter.nih.gov/project-details/9879734

## Citation

> US National Institutes of Health, RePORTER application 9879734, Active and Nonlinear Models for Cochlear Mechanics (5R01DC004084-18). Retrieved via AI Analytics 2026-05-23 from https://api.ai-analytics.org/grant/nih/9879734. Licensed CC0.

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